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On 5/28/2024 9:04 PM, Richard Damon wrote:But note, x, being a Turing Machine, is NOT a "template"On 5/28/24 12:16 PM, olcott wrote:We have not gotten to that point yet this post is so thattypedef int (*ptr)(); // ptr is pointer to int function in C>
00 int H(ptr p, ptr i);
01 int D(ptr p)
02 {
03 int Halt_Status = H(p, p);
04 if (Halt_Status)
05 HERE: goto HERE;
06 return Halt_Status;
07 }
08
09 int main()
10 {
11 H(D,D);
12 return 0;
13 }
>
When Ĥ is applied to ⟨Ĥ⟩
Ĥ.q0 ⟨Ĥ⟩ ⊢* embedded_H ⟨Ĥ⟩ ⟨Ĥ⟩ ⊢* Ĥ.qy ∞
Ĥ.q0 ⟨Ĥ⟩ ⊢* embedded_H ⟨Ĥ⟩ ⟨Ĥ⟩ ⊢* Ĥ.qn
>
*Formalizing the Linz Proof structure*
∃H ∈ Turing_Machines
∀x ∈ Turing_Machines_Descriptions
∀y ∈ Finite_Strings
such that H(x,y) = Halts(x,x)
But since for x being the description of the H^ built from that H and y being the same, it turns out that no matter what answer H gives, it will be wrong.
>
you can fully understand what templates are and how they work.
But the problem is that even in your formulation, H and D are, when doing the test, SPECIFIC PROGRAMS and not "templates" as Halts is defined on the domain of PROGRAMS.(And I think you have an error in your reference to Halts, I think you mean Halts(x,y) not Halts(x,x)Yes good catch. I was trying to model embedded_H / ⟨Ĥ⟩
>
and then changed my mind to make it more general.
The whole purpose here is to get you to understand what>>
*Here is the same thing applied to H/D pairs*
∃H ∈ C_Functions
∀D ∈ x86_Machine_Code_of_C_Functions
such that H(D,D) = Halts(D,D)
Not the same thing.
∃H ∈ C_Functions
is not equivalent to
∃H ∈ Turing_Machines
>
as there are many C_Functions that are not the equivalent of Turing Machines.
>
templates are and how they reference infinite sets.
while the ∃H part can create a set of machines, each element of that set is INDIVIDUALLY TESTED in the following conditions, so, when we get to your test H(x,y) = Halts(x,x), each of H, x, y are individual members of the set, and we THEN collect the set of all of them.>∃H ∈ Turing_Machines>>
In both cases infinite sets are examined to see
if any H exists with the required properties.
>
Yes, but the logic of Turing Machines looks at them one at a time, and the input is a FULL INDEPENDENT PROGRAM.
>
That does not look at one machine it looks as an infinite set of
machines. I am very happy to find out that you were not playing head
games. Linz actually used the words that you referred to.
I understand how they work, the problem is you think they somehow change the meaning of the final condition.I'm not sure what you can define your computation system to be actually based on, and what its supposed use is, since your 'decider' and 'input' are so intertwined.The whole purpose here is to get you to understand what
>
templates are and how they reference infinite sets.
And you are just showing that YOU don't understand it, as it doesn't get you anywhere closer to you goal.And your supposed algorithm just doesn't work when you try to make you system "Turing Complete" by letting D have the ability to have a COPY of H, and being able to make copies of its input, like real Turing machines can.The whole purpose here is to get you to understand what
>
templates are and how they reference infinite sets.
All the other issues are for another different post.
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